Physical optics -- counting interfence fringes to measure a length change

Oct 24, 2019

denniszhao

Homework Statement: Monochromatic light with wavelength λ=650nm is used to determine the coefficient of thermal expansion, α, of a particular metal. The apparatus is shown below. Light is projected from above and passes through the glass and reflects off the cylinder with initial length l0=15.0cm. The gap between the glass and the cylinder is very thin. Consequently, the reflected light contains an interference pattern with alternating light and dark fringes. As the temperature of the cylinder is raised, it expands and the width of the gap decreases. A researcher observes 450 fringe shifts when the temperature increases by ∆T=40.0K. What is the coefficient of thermal expansion for the metal?
I was tryna combine this two formulas to find out the thermal expansion coefficient α but the answer is incorrect.

Relevant Equations: Thermal expansion: ∆l=l0*α*∆T
Optics: ∆l=mλ

Last edited by a moderator: Oct 24, 2019

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Oct 24, 2019

BvU

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I was tryna combine this two formulas to find out the thermal expansion coefficient α but the answer is incorrect.

Post your work, so we can try to find why and from where ...

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Oct 24, 2019

kuruman

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It looks like you did not consider that the light travels twice the distance between the back of the glass and the end of the rod.

1. How does counting interference fringes measure a length change?

Counting interference fringes is based on the principle of interferometry, where the interference pattern created by the combination of two or more light waves can be used to measure small changes in length. When an object is placed in one of the beams of light, it causes a phase shift in the light waves, resulting in a change in the interference pattern. By counting the number of fringes that have shifted, the change in length can be calculated.

4. What are some common applications of counting interference fringes to measure length changes?

This method is commonly used in scientific research and industrial applications for precise measurements of length changes in objects, such as in materials testing, MEMS (Micro-Electro-Mechanical Systems) devices, and interferometric sensors. It is also used in fields such as astronomy and metrology.

5. Are there any limitations to using interference fringes for measuring length changes?

One limitation is that the object being measured must be transparent, as the method relies on the interference of light waves passing through the object. Additionally, environmental factors such as vibrations or temperature changes can affect the accuracy of the measurements.

Physical optics -- counting interfence fringes to measure a length change

Related to Physical optics -- counting interfence fringes to measure a length change

1. How does counting interference fringes measure a length change?

2. What is the accuracy of using interference fringes to measure length changes?

3. Can this method be used for measuring any type of length change?

4. What are some common applications of counting interference fringes to measure length changes?

5. Are there any limitations to using interference fringes for measuring length changes?

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